Method and apparatus for dormant mode support with paging

ABSTRACT

Apparatuses and methods are disclosed herein for implementing dormant mode with paging in a WLAN. Power savings in the computing device and reduction in traffic across the network are achieved by requiring a computing device to inform the WLAN of its location only when it crosses a paging area boundary or is to receive IP traffic. Dormant mode with paging is implemented in a protocol that supports dormant functionality and paging functionality but does not itself provide methods or standards for implementing such functionality, such as the IEEE 802.11. The methods and apparatuses disclosed herein provide the methods needed to implement dormant mode with paging in such a protocol. Generally, the methods and apparatuses for implementing dormant mode with paging basically include (1) establishing paging areas; (2) communicating access group information to a computing device; and (3) locating a computing device.

PRIORITY

This application is a divisional of application Ser. No. 11/336,236,entitled METHOD AND APPARATUS FOR DORMANT MODE SUPPORT WITH PAGING,”filed Jan. 19, 2006, which is a divisional of application Ser. No.10/264,807, entitled “METHOD AND ASSOCIATED APPARATUS FOR DORMANT MODESUPPORT WITH PAGING,” filed Oct. 4, 2002, which claims priority based onthe U.S. Provisional Patent Application No. 60/352,423, entitled “METHODAND ASSOCIATED APPARATUS FOR DORMANT MODE SUPPORT WITH PAGING IN IEEE802.11,” filed Jan. 28, 2002, all assigned to the corporate assignee ofthe present invention and which is incorporated by reference herein.

BACKGROUND

Local area networks (“LAN”) have enabled digital networking of almostany computing device, including, computers, laptops, personal digitalassistants, scanners and any other devices that deal with digitalinformation. However, traditionally, the physical reach of LANs has beenlimited because they require a physical or hard-wired connection betweencomputing devices. Even with phone dial-ups, a LAN network is ultimatelylimited by its hard-wired nature. To overcome this limitation, wirelesssolutions were developed.

In a wireless LAN (“WLAN”), network connections are accomplished by useof a wireless technology such as radio frequency (“RF”), infra-red,microwave, millimeter wave or other type of wireless communicationinstead of cable. This allows a computing device to remain connected tothe network while it is mobile or while it is not physically connectedto the WLAN. The connection is usually accomplished and maintainedthrough the use of an interface card installed in the computing device.WLANs may also include connections to a wired network, such as a LAN.Connections to the wired network are accomplished through the use ofaccess points. Access points are connected to a node using some type ofwired connection. An access point can reside at any node on the wirednetwork and acts as a gateway for routing data (“IP traffic”) betweenthe wired and wireless portions of the network.

Several protocols have been proposed to standardize WLANs to allowgreater compatibility with a wide range of devices, networks andcomponents. One such protocol is the IEEE 802.11. The IEEE 802.11protocol specifies both the architectures and layers of a WLAN. The IEEE802.11 protocol specifies the physical and medium access control (“MAC”)layers of a WLAN. The physical layer handles the wireless transmissionof data, and is generally a form of RF or infrared communication. TheMAC layer is a set of protocols which is responsible for maintainingorder.

With regard to architecture, the IEEE 802.11 protocol specifies twotypes. The first, shown in FIG. 1, is the ad hoc network. The ad hocnetwork can be spontaneously created with a plurality of computingdevices. As shown in FIG. 1, the ad hoc network has no structure, nofixed points and generally, every computing device can communicate withevery other computing device. The second type of architecture is theinfrastructure. As shown in FIG. 2, this architecture uses access pointsthrough which the computing devices can communicate with each other anda node of a wired network (hereinafter “node”). Computing devicescommunicate with an access point through some type of wirelesstechnology and the access points communicate with a node through sometype of wired technology. Nodes can communicate with each other throughvarious types of networks, such as the Internet, generally by some typeof wired connection. A distribution system, which is the mechanism bywhich the access points communicate with each other, is included in theaccess points, and also includes the Nodes, networks, and theconnections among them. Each access point has a range over which itprovides service. Each of these ranges is a basic service set (“BSS”);while the BSS and the distribution system form an extended service set(“ESS”) which defines the range over which services can be provided. Thelocation of the computing device on the network is determined by theaccess point to which it is connected.

A computing device can move about within the range of the access pointto which it is connected. If the WLAN is designed so that there is someoverlap of the ranges of the access points, it may be possible for acomputing device to move among the access points and remain connected tothe WLAN and continue to send and receive IP traffic. In order to dothis, the WLAN needs to know where the computing device is so that itknows where to direct IP traffic intended for the computing device. Inother words, the WLAN must track the computing device.

Generally, in order for the network to track the computing device, thecomputing device associates with an access point at a given timeinterval, upon its movement or when the computing device travels betweenor among the ranges of different access points. IP traffic intended forthe computing device is forwarded to the last access point with whichthe computing device had associated and then forwards the IP traffic tothe computing device. However, tracking and forwarding IP traffic to thecomputing device in this manner can lead to a power drain on thecomputing device and a high level of signaling over the network. Forexample, if the computing device must associate with a new access pointwhenever it enters the range of the new access point, the computingdevice must remain on at all times so that it may detect when it hasentered the range of the new access point. Additionally, the computingdevice must remain on at all times to receive any incoming IP traffic.This continuous detection and repeated associating causes a tremendousdrain on the computing device's power supply and adds to the signalingacross the network.

To overcome these disadvantages, the IEEE 802.11 protocol includesdormant mode functionality. Dormant mode functionality (without pagingfunctionality) allows a computing device to operate in two modes, an“active” mode and a “dormant” mode. In the active mode, the computingdevice can receive signals, such as IP traffic, and can send signalssuch as those sent when the computing device associates with an accesspoint. In the dormant mode, the computing device is not turned off, butis put into a mode which reduces its ability to receive IP traffic byreducing the monitoring of certain channels and thus is a state ofreduced power consumption. The computing device must be in active modeto send or receive IP traffic and associate with an access point.Therefore, the computing device must periodically go into active mode toassociate with an access point and to send or receive IP traffic.Because IP traffic intended for the computing device may be transmittedwhile the computing device is in dormant mode, the IEEE 802.11 protocolincorporates buffers in the access points to queue IP traffic intendedfor the computing device. The computing device can then receive this IPtraffic when it switches into active mode and therefore does not missany IP traffic sent while it was in dormant mode. Although dormant modefunctionality does provide some power savings for the computing deviceand reduced signaling across the network, the computing device muststill periodically switch into active mode to register with each accesspoint of which it is in range, and to send or receive IP traffic.

Further reductions in computing device power drain and signaling acrossthe network can be accomplished through the use of paging. Paging is amethod of notifying a dormant computing device of incoming IP traffic.Paging includes (i) the use of paging areas; and (ii) paging thecomputing device. The use of paging areas includes the creation ofpaging areas and having the computing device signal the network onlywhen it crosses a paging area boundary. A paging area boundary isdefined by the outer perimeter of the ranges of a collection of accesspoints (an “access point group”) that are used to locate a dormantcomputing device. This outer perimeter forms the paging area boundary ofa paging area. Each paging area uniquely identifies itself to computingdevices by periodically broadcasting that paging area's unique pagingarea identifier.

Generally, a network implementing paging will be arranged to have atleast two paging areas. Only when a computing device crosses a pagingarea boundary from one paging area to another, does the computing deviceassociate with the nearest access point. A computing device detects whenit crosses a paging area boundary by detecting a change in the uniquepaging area identifier. However, because neighboring paging areasusually overlap with each other to prevent gaps in coverage, a computingdevice may be in more than one paging area simultaneously and thus willdetect more than one paging area identifier. In this case, the computingdevice will detect the strength of the paging area identifier from eachpaging area that computing device is within and will associate with thepaging area from which the strongest paging area identifier isbroadcast.

The computing device is programmed to periodically go from dormant toactive mode so that it may detect the unique paging identifier oridentifiers being broadcast. By requiring a computing device toassociate with the network only when it crosses a paging area boundary,the amount of signaling to the network is decreased and the amount oftime the computing device can remain dormant is increased, thus powerconsumption is decreased. Further reduction in power usage and signalingby the computing device is realized because the computing device onlyperiodically needs to switch into active mode.

One of the consequences of reducing the number of instances in which thecomputing device informs the network of its location in thepreviously-described manner is that the network does not know thelocation of the computing device within a given paging area. Because thecomputing device may have moved after the last time it associated withan access point, all that the network knows is that the computing deviceis located somewhere within the paging area in which the access pointwith which the computing device last associated is located (the “oldaccess point”). In order for the network to forward IP traffic to thecomputing device, it must know the access point for which the computingdevice is currently in range (the “new access point”) and alert thecomputing device about the pending IP traffic. The network preciselylocates the computing device within a paging area by paging thecomputing device. Paging the computing device is signaling by thenetwork through the access points directed to locating the computingdevice and alerting it to establish a connection. Paging the computingdevice involves transmitting a request to all the access points in thesame paging area as the old access point. These access points thenbroadcast the paging signal. When the computing device receives thepaging signal it associates with the new access point. Once thecomputing device associates with the new access point, the network knowsthe location of the computing device in terms of the access point inwhich it is in range. The new access point then signals the old accesspoint, the old access point sends any buffered IP traffic to the newaccess point and the new access point delivers the buffered IP trafficto the computing device. Power drain on the computing device andsignaling over the network are reduced because the computing device onlyassociates with a new access point in the same paging area when thecomputing device is paged.

Although many cellular-based wireless WAN protocols support paging, WLANprotocols, such as the IEEE 802.11, do not specifically providestandards or methods for implementing paging. For example, the IEEE802.11 protocol does not have paging areas, a dedicated paging channeland a radio link protocol specifically directed towards locating adormant computing device. Additionally, the IEEE 802.11 and other WLANprotocols lack the protocols for establishing and altering paging areas,associating a computing device with an access point, and performingpaging. Furthermore, existing WLAN protocols do not address the issuesof maintaining synchronization of the access points across each accesspoint group and reducing signal interference among access points.

The advantages of the methods and apparatuses disclosed herein will beapparent from the following summary and detailed description of thepreferred embodiments.

BRIEF SUMMARY

Apparatuses and methods are disclosed herein for implementing dormantmode with paging in a WLAN. Power savings in the computing device andreduction in traffic across the network are achieved by requiring acomputing device to inform the WLAN of its location only when it crossesa paging area boundary or is to receive IP traffic. Dormant mode withpaging is implemented in a protocol that supports dormant functionalitybut does not itself provide methods or standards for implementingdormant mode and paging functionality, such as the IEEE 802.11. Themethods and apparatuses disclosed herein are implemented in such aprotocol and provide the methods needed to implement dormant mode withpaging in such a protocol. Generally, the methods and apparatuses forimplementing dormant mode with paging basically include (1) establishingpaging areas; (2) communicating access group information to a computingdevice; and (3) locating a computing device.

Establishing paging areas generally involves, forming at least twoaccess point groups which includes; (a) defining the structure of theaccess point groups (b) establishing a protocol for communications amongthe access points in each access point group; and (c) establishing aprotocol for manipulating the access point groups.

Paging areas are needed to enable the paging functionality and do soprimarily by using paging groups to define paging area boundaries. Thepaging groups are generally formed from a subset of all the accesspoints within the WLAN or network by defining the structure of theaccess point group which establishes the relationships among the accesspoints. In another implementation, the relationships among the accesspoints in a paging group may be defined by a tree structured distributedgroup model. A tree structured distributed group model has ahierarchical tree structure wherein access points are defined in termsof functionality as “master,” “slave,” or both.

Establishing a protocol for communications among the access points in anaccess point group may include developing a unique protocol or modifyingan existing one such as the IEEE Inter Access Point Protocol (“IAPP”).Establishing a protocol for manipulating access point groups involvesadding operations to the protocol for communications that enable theimplementation of a tree structured distributed model. Implementing atree structured distributed model for an access point group may beaccomplished by extending the operations of IAPP. In order to form andmanipulate a paging group, at least five operations must be added toIAPP. These operations include “join,” “leave,” “group merge,” “groupprune” and “devolution.”

Once access point groups have been formed, they must have some way ofcommunicating their identity to any computing device that is within thepaging area that they define so that the computing devices can belocated. The step of communicating access point group information tocomputing devices generally includes (a) including the access pointgroup's paging area ID in the beacon of each access point in the accesspoint group; (b) assigning a channel over which to broadcast the beacon;(c) awakening the computing device to periodically detect the beacon;and (d) synchronizing the timing of the beacon broadcasts of all theaccess points within an access point group.

Including an access point group's unique paging area ID in the beacon ofeach access point enables one paging group (or paging area) to bedistinguished from another. Each paging group is assigned a uniquepaging area ID and communicates this paging area ID to any computingdevices within that paging group's paging area so that a computingdevice can determine in which paging area it is located. This may beaccomplished using a beacon packet or beacon, such as the beacon in theIEEE 802.11 protocol. Beacons are signals which are periodicallybroadcast to each of the access points and contain a variety ofinformation including the paging area ID.

In assigning a channel over which to broadcast the beacon or otherpacket containing the access point ID, there are several issues toconsider. It is advantageous for adjacent access points to broadcast thebeacon over different channels because this helps avoid interference. Itis also advantageous for the access points to broadcast the beacon orother packet over a different channel than that used to broadcast the IPtraffic because this helps to avoid interference between the IP trafficand the beacon or other packet. However, the more channels that are usedthe more channels a computing device must search every time a computingdevice moves from the range of one access point into the range ofanother. Because there is a conflict in the requirements of channelseparation and minimizing the number of channels, multiple methods ofassigning the channel for beacon broadcasting are required so that theassignment can be optimized for a given situation.

Methods of channel assignment include: (1) static assignment; (2)standard common paging channel assignment; and (3) local common pagingchannel assignment method. In the static assignment method, all theaccess points in the WLAN are assigned the same common channel overwhich to broadcast the IP traffic and the beacon. In the standard commonpaging channel assignment method, the access points are assigned auniversal common channel over which to broadcast the beacon and adifferent common channel over which to broadcast the IP traffic. In thelocal common paging channel assignment method, all the access points inthe same access point group are assigned the same channel for pagingwith no adjacent access paging groups assigned the same paging channeland a channel for IP traffic that is different from any of the pagingchannels.

The timing of the beacon broadcasts for each access point within anaccess point group must be synchronized to occur approximately at thesame time (the “beacon timing”). When the beacon broadcasts in an accesspoint group all occur at the same time, the computing device only needsto be in active mode during the beacon timing no matter with whichaccess point the computing device is associated. Synchronizing thebeacon timing for the access points within an access point groupinvolves the access points and the computing device. As the computingdevice moves from within the range of a first access point to within therange of a second access point, it senses the difference between thebeacon timing of the first access point and the second access point toascertain a “beacon timing difference.” The computing device thencommunicates this beacon timing difference to the second access pointwhich communicates the beacon timing difference to the first accesspoint. The beacon timing of the first or second access point or both aresynchronized.

Locating a computing device includes associating the computing devicewith an access point or access point group whenever it crosses an accesspoint boundary, and whenever it is paged. Whenever a computing devicecrosses an access point boundary, it must associate with a new accesspoint in a new access point group. Whenever a computing device is paged,it must associate with the access point for which it is in range so thatit can receive IP traffic. To associate with an access point, thecomputing device sends a request to associate to the new access point.Thereafter, an association identification (“AID”) is assigned to thecomputing device.

BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWINGS

The methods and apparatuses disclosed herein provide numerousembodiments which will be understood by those skilled in the art basedon the present disclosure. Some of these are described below and arerepresented in the drawings by means of several figures, in which:

FIG. 1 is a diagram of a wireless network with an ad hoc architectureaccording to the prior art;

FIG. 2 is a diagram of a wireless network with an infrastructurearchitecture according to the prior art;

FIG. 3 is a diagram of a WLAN that supports paging according to the apreferred embodiment;

FIG. 4 is a diagram of an access point group that uses a structureddistributed grouping model according to a preferred embodiment;

FIG. 5 is a diagram of IAPP architecture according to the prior art;

FIG. 6A is diagram of an access point and access point group, accordingto a preferred embodiment;

FIG. 6B is a diagram of steps in a join operation, according to apreferred embodiment;

FIG. 6C is a diagram of an access point group after the join operationof FIG. 6B is performed, according to a preferred embodiment;

FIG. 7 is a diagram of steps in a leave operation, according to apreferred embodiment;

FIG. 8A is a diagram of steps in a leave operation according to apreferred embodiment;

FIG. 8B is a diagram of an access group and an access point after theleave operation of FIG. 8A is performed, according to a preferredembodiment;

FIG. 9A is a diagram of a first and a second access group, according toa preferred embodiment;

FIG. 9B is a diagram of steps in a group merge operation, according to apreferred embodiment;

FIG. 9C is a diagram of an access group after the group merge operationof FIG. 10B is performed, according to a preferred embodiment;

FIG. 10A is a diagram of steps of a group prune operation, according toa preferred embodiment;

FIG. 10B is a diagram of a first and a second access group after thegroup prune operation of FIG. 10A is performed, according to a preferredembodiment;

FIG. 11A is a diagram of an access group before a group devolutionoperation is performed, according to a preferred embodiment;

FIG. 11B is a diagram of steps of a group devolution operation,according to a preferred embodiment;

FIG. 11C is a diagram of an access group and a two access points afterthe group devolution operation of FIG. 11B is performed, according to apreferred embodiment;

FIG. 12A is a diagram of the beacon elements in the IEEE 802.11 protocolaccording to the prior art;

FIG. 12B is a is a diagram of the beacon elements in the IEEE 802.11protocol according to a preferred embodiment;

FIG. 12C is a diagram of the format of the paging ID according to apreferred embodiment;

FIG. 13A is a flow chart of a method for beacon synchronization,according to a preferred embodiment;

FIG. 13B is a continuation of the flow chart of 15B; and

FIG. 14 is a diagram of the signals produced by a first access point, asecond access point and a computing device during beaconsynchronization, according to a preferred embodiment.

DETAILED DESCRIPTION

Identical features are marked with identical reference symbols in theindicated drawings. Disclosed herein is a method and apparatus forimplementing dormant mode with paging in a WLAN. The method forimplementing dormant mode with paging basically includes the steps of(1) establishing paging areas; (2) communicating access groupinformation to a computing device; and (3) locating a computing device.Although the following example will describe this method and apparatususing one computing device, it may be used for a plurality of computingdevices. It is to be understood that the following example(s) is (are)for the purpose of explanation and not limitation.

The step of establishing paging areas generally involves, forming atleast two access point groups which includes; (a) defining the structureof the access point groups (b) establishing a protocol forcommunications among the access points in each access point group; (c)establishing a protocol for manipulating the access point groups.

Generally, paging areas are defined by the outermost perimeter of theranges of the outermost access point groups within a paging group. Thisouter most perimeter is the paging area boundary. The paging groups aregenerally formed from a subset of all the access points within the WLANor network by defining the structure of the access point group whichestablishes the relationships among the access points. One example isshown in FIG. 3 wherein a WLAN 400 for which a paging area has beendefined is shown. In this WLAN 400, there are two nodes 402 and 404connected to a network 406, such as the internet, by some type of wiredconnection. A plurality of access points 420, 422, 424, 428, 430 and 432are connected to nodes 402 and 404 via some type of wired connection.The access points 420, 422, 424, 428, 430 and 432 are grouped togetherso that the ranges of the access points 434, 436, 438, 440, 442 and 444define a paging area 450 having a paging area boundary 452.

In another example, the relationships among the access points in apaging group may be defined by a tree structured distributed groupmodel. FIG. 4 shows an access point group 10 wherein the relationshipsamong the access points 12-21 in the access point group 10 are definedby a distributed group model. The paging group 10 is comprised of accesspoints 12-21 and defines a paging area 26. The paging area boundary 28is defined by the outermost perimeters of the ranges 30-39 of the accesspoints 12-21, and encloses the paging area 26.

A tree structured distributed group model has a hierarchical treestructure. In the hierarchical tree structure, each access point isconnected to one or more access points directly below it. Additionally,access points are defined in terms of functionality as “master,”“slave,” or both. A master is an access point to which other accesspoints belong and which has the ability to control the access pointsthat belong to it. In FIG. 4, the master access points are 12, 13, 15,17 and 18. A slave is an access point that belongs to a master. In theaccess point group 10, the slave access points are 13-21. It is possibleto be a master and a slave with the functionality of both at the sametime, such as access points 13, 15, 17 and 18. Additionally, an accesspoint may be the master of more than one access point as are accesspoints 12, 15 and 17. However, an access point may not have more thanone master. If an access point is simultaneously both a master and aslave, the master must follow the slave's attributes. Each access pointgroup has one access point to which all others belong, directly orindirectly. This is called the “root access point” (access point 12).Access points at which the tree structure terminates are called “leafaccess points” (access points 14, 16, 19, 10 and 21). All remainingaccess points are called “intermediate access points” (access points 13,15, 17 and 18).

Establishing a protocol for communications among the access points in anaccess point group may include developing a unique protocol or modifyingan existing one. The IEEE Inter Access Point Protocol (“IAPP”) is anexisting protocol between access points that allows conformant accesspoints from multiple vendors to interoperate on a common distributionsystem. IAPP specifies the functionality of the access points (whichdescribes service primitives), a set of functions and a protocol thatwill allow IP packets to be carried between access points. FIG. 5 showsthe IAPP architecture. The access point management entity or APME 40 isused as the main operational program of the access point, implementingthe access point manufacturer's proprietary features and algorithms. Atree structured distributed model for the access point group isimplemented in the APME.

Establishing a protocol for manipulating access point groups involvesadding operations that enable the implementation of a tree structureddistributed model. Implementing a tree structured distributed model foran access point group in APME may be accomplished by extending theoperations of IAPP. In order to form a paging group, at least fiveoperations must be added to IAPP. These operations include “join,”“leave,” “group merge,” “group prune” and “devolution.” Examples ofthese operations are shown in FIGS. 6A-13B.

The join operation performs the steps needed to add an access point toan existing access point group. The simplest case involves joining oneaccess point to another access point. The first access point will send ajoin request to a second access point. The second access point willpermit the first access point to join with it and will form the treestructure of the access point group with itself as the root accesspoint. It does this by added the first access point to its cluster map(“CMAP”) as a slave. The CMAP is a list of all the access points in theaccess point group. The second access point will then send a join replyback to the first access point. The first and second access points nowform an access point group with the second access point as the rootaccess point and the first access point as the leaf access point.

In order to join an access point to an access point group containingmore than one access point, the joining access point sends a joinrequest to one of the access points in the access point group. If theaccess point receiving the join request is not the root access point ofthe group, it forwards the join request to its master. This step isrepeated until the join request reaches the root access point. The rootaccess point then permits the requesting access point to join by addingit to its CMAP and sending a join reply back to the joining access pointthrough the same access points that forwarded the join request to theroot access point but in reverse order. Before sending the join reply tothe joining access point, the access point that received the joinrequest from the joining access point will add the joining access pointto its CMAP as a slave. However, it is possible for the root accesspoint to deny entry to the requesting access point. For example, if theroot access point may include a limitation on the number of accesspoints that can be included in its access point group, the root accesspoint will deny entry to the requesting access point by communicatingback to the requesting access point a no join reply.

FIGS. 6A-C demonstrate the steps included in one embodiment of the joinoperation. FIG. 6B shows the steps in the join operation while FIG. 6Ashows an access point 60 and an access point group 50 before theoperation is performed and FIG. 6C shows the access point group 50 afterthe operation has been performed. The access point group 50 in FIG. 6Aincludes the root access point 52, an intermediate access point 54 andtwo leaf access points 53 and 55. The access point group 50 defines apaging area 56 with paging area boundary 57. As shown in FIG. 6B, whenaccess point 60 is to be added to access group 50, access point 60 sendsa join request to one of the access points 54 in the access point group50 at time t1. Access point 54 forwards this join request to the rootaccess point at 52 at time t2. The root access point 52 then permitsaccess point 60 to join by adding it to its CMAP and sending a joinreply back to access point 54 at time t3. Access point 54 adds accesspoint 60 to its CMAP as a slave and then forwards the join reply toaccess point 60 at time t4. FIG. 6C shows access point group 50 afterthe forgoing use of the join operation. Access point 60 is part ofaccess point group 50 and is the slave of access point 54. Access pointgroup 50 has an enlarged paging area boundary 59 surrounding an enlargedpaging area 58.

In a further embodiment of the join operation, where a first accesspoint group attempts join a second access point group, the joinoperation is defined so that only the root access point of the firstaccess point may request to join with the second access point group.This prevents slave access points from having more than one master whichwould result if a slave access point would join another access pointgroup. In yet a further embodiment of the join operation, where a firstaccess point group attempts join a second access point group, there isno restriction on which access points in the first access point groupmay request to join a second access point group. However, because aslave access point can only have one master at a time, if a slave accesspoint in the first access point group requests to join the second accesspoint group, the slave access point group must leave the first accesspoint group before the join request will be allowed.

When an access point is to leave an access point group containing morethan one access point, the leaving access point sends a leave request toone of the access points in the access point group. If the access pointreceiving the leave request is not the root access point of the group,it forwards the leave request to its master. This step is repeated untilthe leave request reaches the root access point. The root access pointthen permits the leaving access point to leave by deleting it from theCMAP and sending a leave reply back to the leaving access point throughthe same access points that forwarded the leave request to the rootaccess point but in reverse order. Before sending the leave reply to theleaving access point, the access point that received the leave requestfrom the leaving access point will remove the leaving access point fromits CMAP.

FIG. 7 and FIGS. 6C and 6A demonstrate the steps included in oneembodiment of the leave operation. FIG. 7 shows the steps in the leaveoperation when a leaf access point leaves an access point group, whileFIG. 6C shows the access point group 50 before the leave operation isperformed, and FIG. 6A shows an access point 60 and the access pointgroup 50 after the leave operation has been performed. The access pointgroup 50 in FIG. 6C includes the root access point 52, an intermediateaccess point 54 and three leaf access points 53, 55 and 60. The accesspoint group 50 defines a paging area 58 with paging area boundary 59. Asshown in FIG. 7, when access point 60 is to be removed from access group50, access point 60 sends a leave request to one of the access points 54in the access point group 50 at time t1. Access point 54 forwards thisleave request to the root access point at 52 at time t2. The root accesspoint 52 then permits access point 60 to leave by deleting it from itsCMAP and sending a leave reply back to access point 54 at time t3wherein access point 54 removes access point 60 from its CMAP and thenforwards the leave reply to access point 60 at time t4. FIG. 6A showsaccess point group 50 and access point 60 after the leave operation hasbeen performed. Access point 50 has a reduced paging area boundary 57surrounding a reduced paging area 56.

Another implementation of the leave operation involves removing anintermediate access point from an access point group. In thisimplementation, the intermediate access point is directly connected toits master and three leaf access points and is shown in FIGS. 6C, 9A and9B. Implementing the leave operation to remove an intermediate accesspoint may also be called “grafting” because it involves removing theintermediate access point from an access point group and then rejoiningthe slaves of the leaving access point to the access point group. Theaccess point group 50 in FIG. 6C includes the root access point 52,intermediate access point 54 and three leaf access points 53, 55 and 60.The access point group 50 defines a paging area 58 with paging areaboundary 59. As shown in FIG. 8A, when intermediate access point 54 isto leave access group 50, access point 54 sends a leave request to itsmaster (root access point 52) at time t1. The root access point 52 thenpermits access point 54 to leave by deleting it from its CMAP andsending a leave reply back to access point 54 at time t2. Access point54 then sends a leave request to its slaves, access point 60, 53 and 55,at time t3 Access points 60, 53 and 55 then send leave requests back toaccess point 54 at time t4, at which time access point 55 removes accesspoints 60, 53 and 55 from its CMAP. So that access points 60, 53 and 55are not removed from access point group 50, access points 60, 53 and 55send a join request to root access point 52. Access points 60, 53 and 55and access group 50 go through the join operation as described herein.FIG. 8B shows access point group 50 and access point 55 after theforgoing use of the leave operation. Access point group 50 now has areduced paging area boundary 62 surrounding a reduced paging area 61.

In order to combine two access point groups to form a single accesspoint group, the root access point, and only the root access point, of afirst access point group sends a merge request to one of the accesspoints in a second access point group. If the access point receiving themerge request is not the root access point of the group, it forwards themerge request to its master. This step is repeated until the mergerequest reaches the root access point. The root access point of thesecond access point group then permits the second access point group tomerge with second access point group by adding the first access pointgroup to the CMAP of the root access point of the second access pointgroup and sending a merge reply back to the root access point of thefirst access point group through the same access points in the secondaccess point group that forwarded the merge request to the root accesspoint of the second access point group, but in reverse order. Beforesending the merge reply to the root access point of the first accesspoint group, the access point in the second access point group thatreceived the merge request from the root access point of the firstaccess point group will add the root access point of the first accesspoint group to its CMAP.

FIGS. 9A-9C demonstrate the steps included in one embodiment of themerge operation. FIG. 10B shows the steps in the merge operation, FIG.9A shows two access point groups 70 and 80 before a merge operation isperformed, and FIG. 9C shows the access point group 70 after the mergeoperation has been performed. The access point group 70 in FIG. 9Aincludes the root access point 74, an intermediate access point 76 andtwo leaf access points 75 and 77. The access point group 70 defines apaging area 71 with paging area boundary 72. The access point group 80includes the root access point 84 and two leaf access points 85 and 86.The access point group 80 defines a paging area 81 with paging areaboundary 82. As shown in FIG. 9B, when access point 80 is to be mergedwith access group 70, the root access point 84 of access point group 80sends a merge request to one of the access points 75 in the access pointgroup 70 at time t1. Access point 75 forwards this merge request toaccess point 76 at time t2 and access point 76 forwards the mergerequest on to the root access point 74 of access point group 70 at timet3. The root access point 74 then permits access point group 80 to mergewith access point group 70 by adding access point 84 to its CMAP andsending a merge reply back to access point 76 at time t4. Access point76 then forwards the merge reply to access point 75 at time t5. Accesspoint 75 adds access point 80 to its CMAP and then forwards the mergereply to root access point 84 at time t6. FIG. 9C shows access pointgroup 70 after the forgoing use of the merge operation. Access pointgroup 70 has an expanded paging area 88 defined by an expanded pagingarea boundary 89.

In order for a first access point to cut the access points that directlyor indirectly depend from it, the first access point sends a pruneinquiry request to its master. If the access point receiving the pruneinquiry request is not the root access point of the access point group,the access point receiving the prune inquiry request forwards the pruneinquiry request to its master. This step is repeated until the pruneinquiry request reaches the root access point. The root access pointthen permits the first access point to prune its dependent access pointsby removing the dependent access points from the root access point'sCMAP and sending a prune inquiry reply back to the first access pointthrough the same access points that forwarded the prune inquiry requestto the root access point (the “intermediate access points”), but inreverse order. The prune inquiry reply contains a CMAP which has a listof the dependent access points of the requester access point. Theintermediate access points all remove the dependent access points fromtheir CMAPs. The first access point then sends a prune request to eachof its slave access points. The slave access points then send a prunereply back to the first access point. The first access point thenremoves the slave access points from its CMAP and each slave accesspoint is removed from the access point group of the first access point.The removed slave access points may become the root access point of anew access point group if the slaves have slaves of their own, or theymay stand alone.

FIGS. 6C, 10A and 10B demonstrate the steps included in an example ofone embodiment of the prune operation. FIG. 10A shows the steps in theprune operation, while FIG. 6C shows an access point group 50 before aprune operation is performed, and FIG. 10B shows the access point groups50 and 96 after the prune operation has been performed. As shown in FIG.10A, when access point 54 is to prune access points 55, 53 and 60,access point 54 sends a prune inquiry request to the root access point52 at time t1. The root access point 52 then permits access point 54 toprune its dependent access points 53, 55 and 60 by removing thedependent access points 53, 55 and 60 from root access point's 52 CMAPand sending a prune inquiry reply back to access point 54 at time t2.The prune inquiry reply contains a CMAP containing access point 54'sdependent access points. Access point 54 removes access points 53, 55and 60 from its CMAP and then sends a prune request to access points 53,55 and 60 at time t3. Access points 53, 55 and 60 then sends a prunereply back to access point 54 at time t4. FIG. 10B shows access pointgroup 50 and access points 53, 55 and 60 after the forgoing use of theprune operation. Access point group 50 has a reduced paging area 92defined by a reduced paging area boundary 94. Access points 53, 55 and60, are free-standing access points which are not the member of anyaccess point group.

When a root access point is to leave an access point group, thedevolution operation is used. The devolution operation begins when theroot access point sends a devolution request containing all the CMAPsand a delegation of the root role to its slaves. The slaves then send adevolution reply back to the root access point. The root access pointremoves all the slaves from its CMAP. Each of the slave access pointsthen become the root access point for a new access point group. Each ofthe newly-formed root access points then sends a delegation request toeach of its respective slaves. If any of the slaves is not a leaf accesspoint, then that slave forwards the delegation request its slaves. Thisforwarding process continues until every leaf access point receives thedelegation request. Each slave then sends back a delegation reply to itsrespective newly-formed root access point.

FIGS. 11A, 11B and 11C demonstrate the steps included in one embodimentof the devolution operation. FIG. 11A shows an access point group 500before a devolution operation is performed, FIG. 11B shows the steps inthe devolution operation, and FIG. 11C shows two access points 504 and508 and access point group 520 after the devolution operation has beenperformed. Access point group, as shown in FIG. 11A, includes a rootaccess point 504, intermediate access points 506 and 508 and leaf accesspoints 510, 512 and 514. Access group 500 has a paging area 501 definedby a paging area boundary 502. As shown in FIG. 11B, when root accesspoint 504 is to leave access point group 500, access point 504 sends adevolution request containing all the CMAPs to its slave access points506 and 508 at time t1. Access points 506 and 508 then send a devolutionreply to root access point 504 at time t2. Root access point 504 thenremoves the dependent access points 508, 508, 510, 512 and 514 from itsCMAP. Access point 506 then sends a delegation request to its slaveaccess points 510, 512 and 514 at time t3. Access points 510, 512 and514 then send a delegation reply back to access point 504 at time t4.FIG. 11C shows a new access point group 520 and access point 504 and 508after the forgoing use of the devolution operation. New access pointgroup 520 has a paging area 522 defined by a paging area boundary 524.

Once access point groups have been formed, they must have some way ofcommunicating their identity to any computing device that is within thepaging area that they define so that the computing devices can belocated. The step of communicating access point group information tocomputing devices generally includes the steps of (a) including theaccess point group's paging area ID in the beacon of each access pointin the access point group; (b) assigning a channel over which tobroadcast the beacon; (c) awakening the computing device to periodicallydetect the beacon; and (d) synchronizing the timing of the beaconbroadcasts of all the access points within an access point group.Although the following examples will discuss these methods with regardto a single computing device for clarity, the methods may also beapplied when a plurality of computing devices are present.

The step of including an access point group's unique paging area ID inthe beacon of each access point enables one paging group (or pagingarea) to be distinguished from another. So that a computing device candetermine in which paging area it is located, each paging group isassigned a unique paging area ID and communicates this paging area ID toany computing devices within its respective paging area. This may beaccomplished using the beacon packet (hereinafter “beacon”) in the IEEE802.11 protocol.

Beacons provide a mechanism for access points in an access group tocommunicate with each other. The beacon is a signal that is periodicallybroadcast by each of the access points and can contain a variety ofinformation. Each packet of information in the beacon is called an“element.” The beacon included in the IEEE 802.11 protocol contains theelements 110 shown in FIG. 12A. The elements are identified by anelement name and an element ID. Element IDs 32-255 are reserved andtherefore available for use. FIG. 12B shows the enhanced elements 110which contain a paging area ID 112 at one of the formerly-reservedelements, element ID 32. The other reserved elements 114 remainavailable for use.

FIG. 12C shows the format of the paging area ID 120. This formatincludes a one octet space for the element ID, a one octet space for thelength of the paging area ID 124, and an eight octet space for thepaging area ID itself 128. The paging area ID can include one or both ofEUI 48 and EUI 64 (the MAC address). Alternatively, the paging area IDcan include any other indicator so long as that indicator is unique toeach paging area. Additionally, the size of the space used for thepaging area ID (an eight octet space as shown in FIG. 12C) can be variedto accommodate paging area IDs of different lengths. Furthermore, thepaging area ID can be included in any of the other packets broadcast bythe access points. By including the paging area ID as an element in thebeacon of the IEEE 802.11 protocol or other broadcast packet, the pagingarea ID will be periodically broadcasted by each access point in anaccess point group every time the beacon or other packet is broadcastthroughout the range of each access point, respectively.

In assigning a channel over which to broadcast the beacon or otherpacket containing the access point ID, there are several issues toconsider. It is advantageous for adjacent access points to broadcast thebeacon over different channels because this helps avoid interference. Itis also advantageous for the access points to broadcast the beacon orother packet over a different channel than that used to broadcast the IPtraffic because this helps to avoid interference between the IP trafficand the beacon or other packet. Although the IEEE 802.11 protocol'sphysical layer defines multiple channels, the more channels that areused the more channels a computing device must search every time acomputing device moves from the range of one access point into the rangeof another. Clearly there is a conflict in the requirements of channelseparation and minimizing the number of channels. Therefore, severalmethods of assigning the channel which will be used to broadcast thebeacon are provided so that the assignment can be optimized for a givensituation.

Methods of channel assignment include: (1) static assignment; (2)standard common paging channel assignment; and (3) local common pagingchannel assignment method. In the static assignment method, all theaccess points in the WLAN are assigned the same common channel overwhich the IP traffic and the beacon or other packet containing thepaging area ID will be broadcast.

In the standard common paging channel assignment method, a single pagingchannel is assigned to all the access points in the WLAN. The accesspoints are assigned a common channel over which to broadcast the beaconor other packet containing the paging area ID (the “beacon channel”) anddifferent common channel over which to broadcast the IP traffic (the “IPchannel”). This method can reduce the need for a computing device tosearch for the beacon channel and can eliminate the risk of interferencebetween the beacon channel and the IP channel. However, there is still arisk of interference among the broadcasts of adjacent access points.Although this method can eliminate the need for a computing device tosearch for the beacon broadcast, there is a risk of interference betweenthe beacon or other packet and the IP traffic. Additionally, there is arisk of interference among the broadcasts of adjacent access points.

The local common paging channel helps to reduce the risk of interferenceamong the broadcasts of adjacent access points. In the local commonpaging channel assignment method, all the access points in the sameaccess point group are assigned the same paging channel. However, noadjacent access paging groups are assigned the same paging channel. TheIP channel is a channel which is different from any of the pagingchannels. Generally, the paging channel for each access point group isassigned by that access point group's root access point. Additionally,each slave access point uses the same paging channel as its master andnone of the slave access points uses the paging channel as its IPchannel. In this approach, the computing device need only search for thepaging channel when it crosses a paging area boundary because all theaccess points in the access point group have the same paging area ID.Additionally, assigning different beacon channels to adjacent accesspoint groups helps to reduce the risk of interference among the beaconchannels of these groups.

No matter the method of channel assignment used, in order for acomputing device to detect a beacon or other packet, it must be awakenedfrom dormant mode. Once awakened into active mode, the computing devicewill search for the paging channel if the local common paging channelassignment method was used for the beacon or other packet. Generally,the computing device itself is programmed to periodically awaken at setintervals and remain in active mode for a predetermined time period (the“beacon window”). However, the set intervals and beacon window need togenerally correspond with the timing of the beacon broadcast (the“beacon timing”) of the access points.

Synchronizing the beacon timing of all the access points within anaccess point group not only allows the computing device to awaken fromdormant mode only periodically, it enhances the battery life of thecomputing device. Access points need to continuously and periodicallybroadcast their paging area ID so that the access points can berecognized by a computing device when the computing device crosses apaging area boundary. As noted above, the computing device mustperiodically awaken from dormant mode to detect the beacon or otherpacket containing the paging area ID. However, frequent awakening causesheavy battery consumption. To save battery consumption, the number ofawakenings needs to be reduced. If the access points in the same accesspoint group all broadcast their beacons or other packets at the sametime, the computing device only needs to awaken during the period oftime during which the beacon is broadcast, even if the computing devicehas crossed from within the range of one access point into that ofanother.

If all the access points in an access point group are in the same subnetof the WLAN, the access points can adjust their beacon timings tocoincide with the beacon timings of the other access points using thelocal subnet broadcast which can be realized by IAPP. However, if someof the access points in an access point group reside in differentsubnets, transition delays and router queuing delays make the localsubnet broadcast an imprecise mechanism for synchronizing the beacontimings. Therefore, if all the access points in an access point groupare not in the same subnet, synchronizing the beacon timing of all theaccess points cannot be accomplished using the distribution system.Instead synchronization is achieved by using the computing device'stiming reports. The computing device's timing reports contain at least abeacon timing difference.

The method used for synchronizing the beacon timings of all the accesspoints in an access point group is shown in FIGS. 13A and 13B.Initially, as shown in FIG. 13A, when a computing device enters a pagingarea (“the first paging area”), the computing device registers with theaccess point of which it is in range (the “first access point”) 202. Thecomputing device then listens for an initial beacon from the firstaccess point 204. As it listens, the computing device determines whetherit senses the initial beacon 204. If the computing device does not sensethe initial beacon, it continues to listen 204 until it determines thatit has sensed the initial beacon 206. The initial beacon (as do allbeacons) contains the beacon timing for the access point group of whichthe first access point is a member. The beacon timing lets the computingdevice know when to anticipate the next beacon. Upon sensing the initialbeacon, the computing device sets its set intervals to the group beacontiming 208 and then goes into dormant mode 210. The computing devicewill now anticipate beacons according to the group beacon timing.

While in dormant mode, the computing device may remain stationary, movewithin the range of the first access point, move into the range ofanother access point within the first paging area (the “second accesspoint”) or move into a second paging area 212. If the computing deviceremains stationary, moves within the range of the first access point ormoves into the range of a second access point, it will awaken at its setinterval (now set to the group beacon timing) 214 and listen for a newbeacon 216. The new beacon will either be the first access point'sbeacon, or it will be the second access point's beacon if the computingdevice has moved into the range of the second access point. Thecomputing device then determines whether it senses a new beacon duringthe beacon window 218. If it determines that it has sensed a beaconduring the beacon window, the timing of the new beacon and the setinterval of the computing device are already synchronized. Therefore,the computing device returns to dormant mode 210 and steps 210-218 arerepeated until the computing device determines that it does not sense anew beacon during its beacon window 218.

If the computing device determines that it has not sensed a new beaconduring its beacon window 218, the set intervals and the timing of thenew beacon are not synchronized. Therefore, the computing device remainsin active mode until it determines that it does sense a new beacon fromwhich it calculates a beacon timing difference 220. The beacon timingdifference is the difference in time between the beginning of the beaconwindow during which a new beacon was anticipated by the computing deviceand the time when the new beacon is actually sensed by the computingdevice. If the new beacon did not come from the second access point 221,it came from the first access point. This means that the computingdevice has stayed within range of the first access point and the setinterval of the computing device is not synchronized with the beacontiming of the first access point. Therefore, the computing device sendsa beacon timing report containing at least the beacon timing differenceto the first access point 250. The computing device then sets its timerto the beacon timing of the first access point 252 and the computingdevice returns to dormant mode 210 and the process continues from step210.

If the new beacon is from the second access point 221, this means thatthe computing device has moved into the range of the second accesspoint. The computing device sends the beacon timing report including atleast the beacon timing difference and an identification of the firstaccess point to the second access point 222. Then it is determined ifthe second access point is the master of the first access point 226. Thesecond access point makes this determination from the identification ofthe first access point in the beacon timing report. If the second accesspoint is the master of the first access point, the beacon timing of thefirst access point is set to that of the second access point 228. Theset intervals of the computing device are also set to the beacon timingof the second access point 230. If, however, the second access point isnot the master of the first access point 226, it must be determinedwhether the first access point is the master of the second access point232. If the first access point is the master of the second access point,the beacon timing of the second access point is set to that of the firstaccess point 234. Then the set intervals of the computing device are setto the beacon timing of the first access point 238. In contrast, if thefirst access point is not the master of the second access point, thebeacon timings of the first and second access points are set to that oftheir common master 236. The set interval of the computing device isthen also set to the beacon timing of the common master 237. After theset interval of the computing device is set in any of steps 230, 237 or238, whichever access point had changed its beacon timing (the firstaccess point, the second access point or both) notifies the other accesspoints in the access point group of the change in their beacon timing.However, if the first and second access points are in different pagingareas, as indicated by the paging area ID included in the beacon, thecomputing device will not synchronize the first and second accesspoints.

An example of the signaling activity involved in beacon synchronizationis shown in FIG. 14. In this example, a computing device moves fromwithin the rage of a first access point to within the range of a secondaccess point at a time t8 wherein the beacon timings of the two accesspoints are not synchronized. Additionally, both access points arelocated in the same access point group and the first access point is themaster of the second access point. The signal for the computing device360 is indicated as “low” when the computing device is in dormant modeand is indicated as “high” when the computing device is in active mode.The signals of the first access point 320 and the second access point322 are divided into a plurality of segments. Each segment 322 and 342,respectively, has the duration of approximately the duration of thebeacon of each access point, respectively. The computing device iswithin the range of the first access point during a first time period324 and moves within the range of the second access point at a time t8and remains there during a second time period 326. Although the secondaccess point is broadcasting its beacon 344 and 348 during the firsttime period 324, the computing device does not sense these beacons 344and 348 because the computing device is not within the range of thesecond computing device during the first time period 324. Subsequently,the computing device moves into the range of the second access point attime t8, is within the range of the second access point during a secondtime period 326 and remains there during a second time period 326.Although the first access point is broadcasting its beacon 332, 334 and336 during the second time period 326, the computing device does notsense these beacons 332, 334 and 336 because the computing device is notwithin the range of the first computing device during the second timeperiod 326.

Initially when the computing device is within the range of the firstaccess point during the first time period 324, the computing device'ssignal is “high” at time t1. The first access point broadcasts itsbeacon 328 between time t2 and t3. After the first access point's beacon328 has been broadcast, the computing device returns to dormant mode attime t4 (the signal of the computing device becomes “low”). Because thefirst access point's beacon 328 contains the beacon timing, thecomputing device knows when to anticipate the first access point's nextbeacon. Therefore, at time t5, a short time before the first accesspoint's beacon 330 is anticipated, the computing device's signal goes“high” and remain “high” until the first access point has completedbroadcasting the first access point's beacon 332.

At time t8, the beginning of the second time period 326, the computingdevice moves from within the range of the first access point to withinthe range of the second access point. However, just prior to its move attime t7, the computing device had anticipated the next beacon 332 fromthe first access point. If the beacon timings of the first and secondaccess points were synchronized, the computing device should sense thesecond access points beacon shortly after time t7. Because the beacontimings of the first and second access points are not synchronized, thecomputing device does not sense the second access point's beacon at timet8 but instead at time t9. Therefore, the signal of the computing devicemust remain “high” until time t10 when the second access point hascompleted the broadcast of its beacon 350.

In order to synchronize the beacon timings of the first access point andthe second access point, the computing device calculates the beacontiming difference 362. In this case, the beacon timing difference 362 isthe difference between time t10 (when the broadcast of the second accesspoint's beacon 350 is complete) and time t7 (shortly before thebroadcast of the first access point's beacon 332 was anticipated). Thecomputing device then sends the beacon timing difference to the secondaccess point. The second access point identifies the first access pointusing IAPP and the Service Location Protocol (“SLP”). Because the firstaccess point is the master of the second access point, the second accesspoint must adjust its beacon timing to that of the first access point.

Because at this point the last beacon sensed by the computing device isthe second access point's beacon 350 and beacon 350 contains theunsynchronized beacon timing of the second access point, the signal ofthe computing device will go “high” at time t11 just before thecomputing device anticipates the next beacon at time t12. Therefore,before adjusting its beacon timing to that of the first access point,the second access point broadcasts one more beacon 352 according to itsoriginal beacon timing at t12. However, beacon 352 contains a beacontiming adjusted to that of the first access point. The computingdevice's signal will go “low” at time t13 after the broadcast of beacon352 is complete. The computing device's signal will go “high” again att14 just before the second access point's next beacon 354 is anticipatedaccording to the adjusted beacon timing.

The step of locating a computing device includes associating thecomputing device whenever it crosses an access point boundary andwhenever it is paged. Whenever a computing device crosses an accesspoint boundary, it must associate with a new access point group. Inorder to associate with a new access point group, the computing devicewill communicate with an access point in the access point group of whichthe computing device is in range (the “in-range access point”). Morespecifically, to associate with a new access point group, the computingdevice sends a request to associate to the in-range access point. Theroot access point of the new access point group, which may be thein-range access point, then assigns an association identification(“AID”) to the computing device and adds the AID and the associated MACaddress of the computing device to its association table. The A/D willtypically have a value of in the range of about 1 to about 2007 and isplaced in the 14 least significant bits of the AID field with the twoleast significant bits of the AID filed each set to “1.” The root accesspoint of the new access point group will then communicate the MACaddress and AID of the computing device to the other access points inthe new access point group. This communication occurs during associationand thru the use of IAPP to broadcast the IAPP-ADD.request (whichincludes the MAC address and AID of the computing device) over the localsubnet broadcast using IAPP to all the access points on the same subnet.This communicates the MAC address of the computing device to the accesspoints on the same subnet as the root access point. For access points inthe access point group that are not on the same subnet as the rootaccess point, IAPP may also be used to communicate the MAC address ofthe computing device. Because the MAC address is used to identify thecomputing device instead of the IP address, the problems normallyassociated with a computing device moving from one subnet to the otherare avoided.

The AID will remain associated with the computing device and the MACnumber of the computing device will remain in the association tables ofthe access points of the new access point group until the computingdevice explicitly or implicitly disassociates from the new access pointgroup. To disassociate explicitly, the computing device invokes adisassociation service. To disassociate implicitly the computing devicesimply leaves the range of the new access point group without explicitlydisassociating. The new access point group will discover that thecomputing device has left its range without explicitly disassociatingwhen the new access point group does not receive a communication fromthe computing device within a predetermined time period. At this time,the computing device will be disassociated. When the computing devicedisassociates from the access point group, the AID is available to bereused and the computing device's MAC address is deleted from theassociation tables of the access points in the new access point group.

In addition to associating with an access point group, the computingdevice must also associate with an access point when it is paged so thatit can receive IP traffic. Once a computing device has associated withan access point group, that access point group may then receive IPtraffic for that computing device through the root access point. Whenthe root access point receives IP traffic for the computing device, thecomputing device must then be located within the access point group and,if in dormant mode, the computing device must be moved into active mode.Because the location of the computing device within the access pointgroup is unknown, the root access point communicates to the other accesspoints in the access point group that the communication device needs tobe paged. All the access points in the access point group then page thecommunication device. After receiving the page, the communication devicethen sends a request to associate to whichever of the access points thecomputing device is in range. That access point then notifies the rootaccess point of the presence of the computing device within its rangeand the root access point then forwards the IP traffic to that accesspoint. That access point then forwards the IP traffic to the computingdevice. While the computing device is in active mode, if it moves intothe range of a second access point in the same access point group, itwill register with the second access point.

Although the methods and apparatuses disclosed herein have beendescribed in terms of specific embodiments and applications, personsskilled in the art can, in light of this disclosure, generate additionalembodiments without exceeding the scope or departing from the spirit ofthe claimed inventions. For example, the methods and apparatusesdisclosed herein can be implemented in any protocol that supportsdormant mode and paging functionalities. Accordingly, it is to beunderstood that the drawings and descriptions in this disclosure areproffered to facilitate comprehension of the invention and should not beconstrued to limit the scope thereof.

1. A WLAN, comprising: a means for establishing paging areas; a meansfor communicating access group information to a computing device; and ameans for locating a computing device within the WLAN.
 2. A method forimplementing dormant mode with paging in a WLAN, comprising:establishing paging areas; communicating access group information to acomputing device; and locating a computing device.